Related papers: Locally purified density operators for noisy quantum circuits

Locally purified density operators for noisy quantum circuits

URL: http://arxiv.org/abs/2312.02854v2
Date: Mon, 3 Jun 2024 13:38:12 GMT
Title: Locally purified density operators for noisy quantum circuits
Authors: Yuchen Guo, Shuo Yang,
Abstract summary: We show that mixed states generated from noisy quantum circuits can be efficiently represented by locally purified density operators (LPDOs) We present a mapping from LPDOs of $N$ qubits to projected entangled-pair states of size $2times N$ and introduce a unified method for managing virtual and Kraus bonds.
Score: 17.38734393793605
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Simulating open quantum systems is essential for exploring novel quantum phenomena and evaluating noisy quantum circuits. In this Letter, we address the problem of whether mixed states generated from noisy quantum circuits can be efficiently represented by locally purified density operators (LPDOs). We present a mapping from LPDOs of $N$ qubits to projected entangled-pair states of size $2\times N$ and introduce a unified method for managing virtual and Kraus bonds, which is numerically validated by noisy random quantum circuits with depths up to $d=40$, using fidelity and entanglement entropy as accuracy measures. LPDO representation proves to be effective in describing mixed states in both quantum and classical regions but encounters significant challenges at the quantum-classical critical point, limiting its applicability to the quantum region exclusively. In contrast, the matrix product operator (MPO) successfully characterizes the entanglement trend throughout the simulation, while truncation in MPOs breaks the positivity condition required for a physical density matrix. This work advances our understanding of efficient mixed-state representation in open quantum systems and provides insights into the entanglement structure of noisy quantum circuits.

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